Suppression of von K\'arm\'an vortex streets past porous rectangular cylinders

TL;DR

This study investigates how porosity and permeability influence wake patterns and vortex shedding suppression behind porous rectangular cylinders using numerical simulations and stability analyses.

Contribution

It introduces a modified Darcy-Brinkman model to analyze flow inside porous bodies and identifies permeability thresholds that suppress vortex shedding.

Findings

Permeability significantly alters wake structures and flow instabilities.

Higher permeability leads to detachment and disappearance of recirculation regions.

Critical permeability values can prevent linear flow instabilities and vortex shedding.

Abstract

Although the stability properties of the wake past impervious bluff bodies have been widely examined in the literature, similar analyses regarding the flow around and through porous ones are still lacking. In this work, the effect of the porosity and permeability on the wake patterns of porous rectangular cylinders is numerically investigated at low to moderate Reynolds numbers in the framework of direct numerical simulation combined with local and global stability analyses. A modified Darcy-Brinkman formulation is employed here so as to describe the flow behavior inside the porous media, where also the convective terms are retained to correctly account for the inertial effects at high values of permeability. Different aspect ratios of the cylinder are considered, varying the thickness-to-height ratios, t/d, from 0.01 (flat plate) to 1.0 (square cylinder). The results show that the permeability of the bodies has a strong effect in modifying the characteristics of the wakes and of the associated flow instabilities, while the porosity weakly affects the resulting flow patterns. In particular, the fluid flows through the porous bodies and, thus, as the permeability is progressively increased, the recirculation regions, initially attached to the rear part of the bodies, at first detach from the body and, eventually, disappear even in the near wakes. Global stability analyses lead to the identification of critical values of the permeability above which any linear instability is prevented. Moreover, a different scaling of the non-dimensional permeability allows to identify a general threshold for all the configurations here studied that ensures the suppression of vortex shedding, at least in the considered parameter space.